Emergence of distinct neural subspaces in motor cortical dynamics during volitional adjustments of ongoing locomotion

Abstract

3AbstractThe brain is capable of simultaneously carrying out multiple functions, such as making different types of movements at the same time. One example is how we are able to both carry out stereotyped walking or running movements, while concurrently performing precise, target-directed movements such as kicking a ball in a soccer match. Recently, research has shown that different computations within the same population of neurons can be carried out without disrupting each other by confining the processes into separate subspaces. Whether this strategy is used to precisely control our limbs while maintaining locomotion is still an open question. Here, we recorded the activity of primary motor cortex in nonhuman primates during obstacle avoidance on a treadmill. We found that the same neural population was active during both basic unobstructed locomotion and volitional obstacle avoidance movements. Additionally, we identified the neural modes spanning the subspace of the low-dimensional dynamics in M1 using both supervised and unsupervised techniques. We found that motor cortex employs a subspace that consistently maintains the same cyclic activity throughout obstacle stepping, despite large changes in the movement itself. All the variance corresponding to the large change in movement during the obstacle avoidance is confined to its own distinct subspace. Our findings suggest that M1 utilizes different activity subspaces to coordinate the maintenance of ongoing locomotor-related neural dynamics and fast volitional gait adjustments during complex locomotion.4Significance StatementOur ability to modulate our ongoing walking gait with precise, voluntary adjustments is what allows us to navigate complex terrains. Locomotion and precise, goal-directed movements, such as reaching are two distinct movement modalities and have been shown to have differing requirements of motor cortical input. It is unknown how these two movements are represented in M1 low dimensional dynamics when both are carried out at the same time, such as during obstacle avoidance. We developed a novel obstacle avoidance paradigm in freely-moving non-human primates and discovered that the strategy employed by motor cortex is to confine the rhythmic locomotion-related dynamics and the voluntary, gait-adjustment movement into separate subspaces.